6939134: JSR 292 adjustments to method handle invocation
Summary: split MethodHandle.invoke into invokeExact and invokeGeneric; also clean up JVM-to-Java interfaces
Reviewed-by: twisti
/*
* Copyright 2008-2009 Sun Microsystems, Inc. All Rights Reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Sun designates this
* particular file as subject to the "Classpath" exception as provided
* by Sun in the LICENSE file that accompanied this code.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
* CA 95054 USA or visit www.sun.com if you need additional information or
* have any questions.
*/
package sun.dyn;
import java.dyn.JavaMethodHandle;
import java.dyn.MethodHandle;
import java.dyn.MethodHandles;
import java.dyn.MethodType;
import java.dyn.NoAccessException;
import java.lang.reflect.Constructor;
import java.lang.reflect.InvocationTargetException;
import sun.dyn.util.ValueConversions;
import sun.dyn.util.Wrapper;
/**
* Adapters which mediate between incoming calls which are generic
* and outgoing calls which are not. Any call can be represented generically
* boxing up its arguments, and (on return) unboxing the return value.
* <p>
* A call is "generic" (in MethodHandle terms) if its MethodType features
* only Object arguments. A non-generic call therefore features
* primitives and/or reference types other than Object.
* An adapter has types for its incoming and outgoing calls.
* The incoming call type is simply determined by the adapter's type
* (the MethodType it presents to callers). The outgoing call type
* is determined by the adapter's target (a MethodHandle that the adapter
* either binds internally or else takes as a leading argument).
* (To stretch the term, adapter-like method handles may have multiple
* targets or be polymorphic across multiple call types.)
* @author jrose
*/
class FromGeneric {
// type for the outgoing call (may have primitives, etc.)
private final MethodType targetType;
// type of the outgoing call internal to the adapter
private final MethodType internalType;
// prototype adapter (clone and customize for each new target!)
private final Adapter adapter;
// entry point for adapter (Adapter mh, a...) => ...
private final MethodHandle entryPoint;
// unboxing invoker of type (MH, Object**N) => raw return value
// it makes up the difference of internalType => targetType
private final MethodHandle unboxingInvoker;
// conversion which boxes a the target's raw return value
private final MethodHandle returnConversion;
/** Compute and cache information common to all unboxing adapters
* that can call out to targets of the erasure-family of the given erased type.
*/
private FromGeneric(MethodType targetType) {
this.targetType = targetType;
MethodType internalType0;
// the target invoker will generally need casts on reference arguments
Adapter ad = findAdapter(internalType0 = targetType.erase());
if (ad != null) {
// Immediate hit to exactly the adapter we want,
// with no monkeying around with primitive types.
this.internalType = internalType0;
this.adapter = ad;
this.entryPoint = ad.prototypeEntryPoint();
this.returnConversion = computeReturnConversion(targetType, internalType0);
this.unboxingInvoker = computeUnboxingInvoker(targetType, internalType0);
return;
}
// outgoing primitive arguments will be wrapped; unwrap them
MethodType primsAsObj = MethodTypeImpl.of(targetType).primArgsAsBoxes();
MethodType objArgsRawRet = MethodTypeImpl.of(primsAsObj).primsAsInts();
if (objArgsRawRet != targetType)
ad = findAdapter(internalType0 = objArgsRawRet);
if (ad == null) {
ad = buildAdapterFromBytecodes(internalType0 = targetType);
}
this.internalType = internalType0;
this.adapter = ad;
MethodType tepType = targetType.insertParameterTypes(0, adapter.getClass());
this.entryPoint = ad.prototypeEntryPoint();
this.returnConversion = computeReturnConversion(targetType, internalType0);
this.unboxingInvoker = computeUnboxingInvoker(targetType, internalType0);
}
/**
* The typed target will be called according to targetType.
* The adapter code will in fact see the raw result from internalType,
* and must box it into an object. Produce a converter for this.
*/
private static MethodHandle computeReturnConversion(
MethodType targetType, MethodType internalType) {
Class<?> tret = targetType.returnType();
Class<?> iret = internalType.returnType();
Wrapper wrap = Wrapper.forBasicType(tret);
if (!iret.isPrimitive()) {
assert(iret == Object.class);
return ValueConversions.identity();
} else if (wrap.primitiveType() == iret) {
return ValueConversions.box(wrap, false);
} else {
assert(tret == double.class ? iret == long.class : iret == int.class);
return ValueConversions.boxRaw(wrap, false);
}
}
/**
* The typed target will need an exact invocation point; provide it here.
* The adapter will possibly need to make a slightly different call,
* so adapt the invoker. This way, the logic for making up the
* difference between what the adapter can call and what the target
* needs can be cached once per type.
*/
private static MethodHandle computeUnboxingInvoker(
MethodType targetType, MethodType internalType) {
// All the adapters we have here have reference-untyped internal calls.
assert(internalType == internalType.erase());
MethodHandle invoker = MethodHandles.exactInvoker(targetType);
// cast all narrow reference types, unbox all primitive arguments:
MethodType fixArgsType = internalType.changeReturnType(targetType.returnType());
MethodHandle fixArgs = AdapterMethodHandle.convertArguments(Access.TOKEN,
invoker, Invokers.invokerType(fixArgsType),
invoker.type(), null);
if (fixArgs == null)
throw new InternalError("bad fixArgs");
// reinterpret the calling sequence as raw:
MethodHandle retyper = AdapterMethodHandle.makeRetypeRaw(Access.TOKEN,
Invokers.invokerType(internalType), fixArgs);
if (retyper == null)
throw new InternalError("bad retyper");
return retyper;
}
Adapter makeInstance(MethodHandle typedTarget) {
MethodType type = typedTarget.type();
if (type == targetType) {
return adapter.makeInstance(entryPoint, unboxingInvoker, returnConversion, typedTarget);
}
// my erased-type is not exactly the same as the desired type
assert(type.erase() == targetType); // else we are busted
MethodHandle invoker = computeUnboxingInvoker(type, internalType);
return adapter.makeInstance(entryPoint, invoker, returnConversion, typedTarget);
}
/** Build an adapter of the given generic type, which invokes typedTarget
* on the incoming arguments, after unboxing as necessary.
* The return value is boxed if necessary.
* @param genericType the required type of the result
* @param typedTarget the target
* @return an adapter method handle
*/
public static MethodHandle make(MethodHandle typedTarget) {
MethodType type = typedTarget.type();
if (type == type.generic()) return typedTarget;
return FromGeneric.of(type).makeInstance(typedTarget);
}
/** Return the adapter information for this type's erasure. */
static FromGeneric of(MethodType type) {
MethodTypeImpl form = MethodTypeImpl.of(type);
FromGeneric fromGen = form.fromGeneric;
if (fromGen == null)
form.fromGeneric = fromGen = new FromGeneric(form.erasedType());
return fromGen;
}
public String toString() {
return "FromGeneric"+targetType;
}
/* Create an adapter that handles spreading calls for the given type. */
static Adapter findAdapter(MethodType internalType) {
MethodType entryType = internalType.generic();
MethodTypeImpl form = MethodTypeImpl.of(internalType);
Class<?> rtype = internalType.returnType();
int argc = form.parameterCount();
int lac = form.longPrimitiveParameterCount();
int iac = form.primitiveParameterCount() - lac;
String intsAndLongs = (iac > 0 ? "I"+iac : "")+(lac > 0 ? "J"+lac : "");
String rawReturn = String.valueOf(Wrapper.forPrimitiveType(rtype).basicTypeChar());
String cname0 = rawReturn + argc;
String cname1 = "A" + argc;
String[] cnames = { cname0+intsAndLongs, cname0, cname1+intsAndLongs, cname1 };
String iname = "invoke_"+cname0+intsAndLongs;
// e.g., D5I2, D5, L5I2, L5; invoke_D5
for (String cname : cnames) {
Class<? extends Adapter> acls = Adapter.findSubClass(cname);
if (acls == null) continue;
// see if it has the required invoke method
MethodHandle entryPoint = null;
try {
entryPoint = MethodHandleImpl.IMPL_LOOKUP.findSpecial(acls, iname, entryType, acls);
} catch (NoAccessException ex) {
}
if (entryPoint == null) continue;
Constructor<? extends Adapter> ctor = null;
try {
ctor = acls.getDeclaredConstructor(MethodHandle.class);
} catch (NoSuchMethodException ex) {
} catch (SecurityException ex) {
}
if (ctor == null) continue;
try {
// Produce an instance configured as a prototype.
return ctor.newInstance(entryPoint);
} catch (IllegalArgumentException ex) {
} catch (InvocationTargetException wex) {
Throwable ex = wex.getTargetException();
if (ex instanceof Error) throw (Error)ex;
if (ex instanceof RuntimeException) throw (RuntimeException)ex;
} catch (InstantiationException ex) {
} catch (IllegalAccessException ex) {
}
}
return null;
}
static Adapter buildAdapterFromBytecodes(MethodType internalType) {
throw new UnsupportedOperationException("NYI");
}
/**
* This adapter takes some untyped arguments, and returns an untyped result.
* Internally, it applies the invoker to the target, which causes the
* objects to be unboxed; the result is a raw type in L/I/J/F/D.
* This result is passed to convert, which is responsible for
* converting the raw result into a boxed object.
* The invoker is kept separate from the target because it can be
* generated once per type erasure family, and reused across adapters.
*/
static abstract class Adapter extends JavaMethodHandle {
/*
* class X<<R,int N>> extends Adapter {
* (MH, Object**N)=>raw(R) invoker;
* (any**N)=>R target;
* raw(R)=>Object convert;
* Object invoke(Object**N a) = convert(invoker(target, a...))
* }
*/
protected final MethodHandle invoker; // (MH, Object**N) => raw(R)
protected final MethodHandle convert; // raw(R) => Object
protected final MethodHandle target; // (any**N) => R
@Override
public String toString() {
return target.toString();
}
protected boolean isPrototype() { return target == null; }
protected Adapter(MethodHandle entryPoint) {
this(entryPoint, null, entryPoint, null);
assert(isPrototype());
}
protected MethodHandle prototypeEntryPoint() {
if (!isPrototype()) throw new InternalError();
return convert;
}
protected Adapter(MethodHandle entryPoint,
MethodHandle invoker, MethodHandle convert, MethodHandle target) {
super(entryPoint);
this.invoker = invoker;
this.convert = convert;
this.target = target;
}
/** Make a copy of self, with new fields. */
protected abstract Adapter makeInstance(MethodHandle entryPoint,
MethodHandle invoker, MethodHandle convert, MethodHandle target);
// { return new ThisType(entryPoint, convert, target); }
/// Conversions on the value returned from the target.
protected Object convert_L(Object result) throws Throwable { return convert.<Object>invokeExact(result); }
protected Object convert_I(int result) throws Throwable { return convert.<Object>invokeExact(result); }
protected Object convert_J(long result) throws Throwable { return convert.<Object>invokeExact(result); }
protected Object convert_F(float result) throws Throwable { return convert.<Object>invokeExact(result); }
protected Object convert_D(double result) throws Throwable { return convert.<Object>invokeExact(result); }
static private final String CLASS_PREFIX; // "sun.dyn.FromGeneric$"
static {
String aname = Adapter.class.getName();
String sname = Adapter.class.getSimpleName();
if (!aname.endsWith(sname)) throw new InternalError();
CLASS_PREFIX = aname.substring(0, aname.length() - sname.length());
}
/** Find a sibing class of Adapter. */
static Class<? extends Adapter> findSubClass(String name) {
String cname = Adapter.CLASS_PREFIX + name;
try {
return Class.forName(cname).asSubclass(Adapter.class);
} catch (ClassNotFoundException ex) {
return null;
} catch (ClassCastException ex) {
return null;
}
}
}
/* generated classes follow this pattern:
static class xA2 extends Adapter {
protected xA2(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected xA2(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected xA2 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new xA2(e, i, c, t); }
protected Object invoke_L2(Object a0, Object a1) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1)); }
protected Object invoke_I2(Object a0, Object a1) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1)); }
protected Object invoke_J2(Object a0, Object a1) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1)); }
protected Object invoke_F2(Object a0, Object a1) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1)); }
protected Object invoke_D2(Object a0, Object a1) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1)); }
}
// */
/*
: SHELL; n=FromGeneric; cp -p $n.java $n.java-; sed < $n.java- > $n.java+ -e '/{{*{{/,/}}*}}/w /tmp/genclasses.java' -e '/}}*}}/q'; (cd /tmp; javac -d . genclasses.java; java -cp . genclasses) >> $n.java+; echo '}' >> $n.java+; mv $n.java+ $n.java; mv $n.java- $n.java~
//{{{
import java.util.*;
class genclasses {
static String[] TYPES = { "Object", "int ", "long ", "float ", "double" };
static String[] TCHARS = { "L", "I", "J", "F", "D", "A" };
static String[][] TEMPLATES = { {
"@for@ arity=0..10 rcat<=4 nrefs<=99 nints=0 nlongs=0",
" //@each-cat@",
" static class @cat@ extends Adapter {",
" protected @cat@(MethodHandle entryPoint) { super(entryPoint); } // to build prototype",
" protected @cat@(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)",
" { super(e, i, c, t); }",
" protected @cat@ makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)",
" { return new @cat@(e, i, c, t); }",
" //@each-R@",
" protected Object invoke_@catN@(@Tvav@) throws Throwable { return convert_@Rc@(invoker.<@R@>invokeExact(target@av@)); }",
" //@end-R@",
" }",
} };
static final String NEWLINE_INDENT = "\n ";
enum VAR {
cat, catN, R, Rc, av, Tvav, Ovav;
public final String pattern = "@"+toString().replace('_','.')+"@";
public String binding;
static void makeBindings(boolean topLevel, int rcat, int nrefs, int nints, int nlongs) {
int nargs = nrefs + nints + nlongs;
if (topLevel)
VAR.cat.binding = catstr(ALL_RETURN_TYPES ? TYPES.length : rcat, nrefs, nints, nlongs);
VAR.catN.binding = catstr(rcat, nrefs, nints, nlongs);
VAR.R.binding = TYPES[rcat];
VAR.Rc.binding = TCHARS[rcat];
String[] Tv = new String[nargs];
String[] av = new String[nargs];
String[] Tvav = new String[nargs];
String[] Ovav = new String[nargs];
for (int i = 0; i < nargs; i++) {
int tcat = (i < nrefs) ? 0 : (i < nrefs + nints) ? 1 : 2;
Tv[i] = TYPES[tcat];
av[i] = arg(i);
Tvav[i] = param(Tv[i], av[i]);
Ovav[i] = param("Object", av[i]);
}
VAR.av.binding = comma(", ", av);
VAR.Tvav.binding = comma(Tvav);
VAR.Ovav.binding = comma(Ovav);
}
static String arg(int i) { return "a"+i; }
static String param(String t, String a) { return t+" "+a; }
static String comma(String[] v) { return comma("", v); }
static String comma(String sep, String[] v) {
if (v.length == 0) return "";
String res = sep+v[0];
for (int i = 1; i < v.length; i++) res += ", "+v[i];
return res;
}
static String transform(String string) {
for (VAR var : values())
string = string.replaceAll(var.pattern, var.binding);
return string;
}
}
static String[] stringsIn(String[] strings, int beg, int end) {
return Arrays.copyOfRange(strings, beg, Math.min(end, strings.length));
}
static String[] stringsBefore(String[] strings, int pos) {
return stringsIn(strings, 0, pos);
}
static String[] stringsAfter(String[] strings, int pos) {
return stringsIn(strings, pos, strings.length);
}
static int indexAfter(String[] strings, int pos, String tag) {
return Math.min(indexBefore(strings, pos, tag) + 1, strings.length);
}
static int indexBefore(String[] strings, int pos, String tag) {
for (int i = pos, end = strings.length; ; i++) {
if (i == end || strings[i].endsWith(tag)) return i;
}
}
static int MIN_ARITY, MAX_ARITY, MAX_RCAT, MAX_REFS, MAX_INTS, MAX_LONGS;
static boolean ALL_ARG_TYPES, ALL_RETURN_TYPES;
static HashSet<String> done = new HashSet<String>();
public static void main(String... av) {
for (String[] template : TEMPLATES) {
int forLinesLimit = indexBefore(template, 0, "@each-cat@");
String[] forLines = stringsBefore(template, forLinesLimit);
template = stringsAfter(template, forLinesLimit);
for (String forLine : forLines)
expandTemplate(forLine, template);
}
}
static void expandTemplate(String forLine, String[] template) {
String[] params = forLine.split("[^0-9]+");
if (params[0].length() == 0) params = stringsAfter(params, 1);
System.out.println("//params="+Arrays.asList(params));
int pcur = 0;
MIN_ARITY = Integer.valueOf(params[pcur++]);
MAX_ARITY = Integer.valueOf(params[pcur++]);
MAX_RCAT = Integer.valueOf(params[pcur++]);
MAX_REFS = Integer.valueOf(params[pcur++]);
MAX_INTS = Integer.valueOf(params[pcur++]);
MAX_LONGS = Integer.valueOf(params[pcur++]);
if (pcur != params.length) throw new RuntimeException("bad extra param: "+forLine);
if (MAX_RCAT >= TYPES.length) MAX_RCAT = TYPES.length - 1;
ALL_ARG_TYPES = (indexBefore(template, 0, "@each-Tv@") < template.length);
ALL_RETURN_TYPES = (indexBefore(template, 0, "@each-R@") < template.length);
for (int nargs = MIN_ARITY; nargs <= MAX_ARITY; nargs++) {
for (int rcat = 0; rcat <= MAX_RCAT; rcat++) {
expandTemplate(template, true, rcat, nargs, 0, 0);
if (ALL_ARG_TYPES) break;
expandTemplateForPrims(template, true, rcat, nargs, 1, 1);
if (ALL_RETURN_TYPES) break;
}
}
}
static String catstr(int rcat, int nrefs, int nints, int nlongs) {
int nargs = nrefs + nints + nlongs;
String cat = TCHARS[rcat] + nargs;
if (!ALL_ARG_TYPES) cat += (nints==0?"":"I"+nints)+(nlongs==0?"":"J"+nlongs);
return cat;
}
static void expandTemplateForPrims(String[] template, boolean topLevel, int rcat, int nargs, int minints, int minlongs) {
for (int isLong = 0; isLong <= 1; isLong++) {
for (int nprims = 1; nprims <= nargs; nprims++) {
int nrefs = nargs - nprims;
int nints = ((1-isLong) * nprims);
int nlongs = (isLong * nprims);
expandTemplate(template, topLevel, rcat, nrefs, nints, nlongs);
}
}
}
static void expandTemplate(String[] template, boolean topLevel,
int rcat, int nrefs, int nints, int nlongs) {
int nargs = nrefs + nints + nlongs;
if (nrefs > MAX_REFS || nints > MAX_INTS || nlongs > MAX_LONGS) return;
VAR.makeBindings(topLevel, rcat, nrefs, nints, nlongs);
if (topLevel && !done.add(VAR.cat.binding)) {
System.out.println(" //repeat "+VAR.cat.binding);
return;
}
for (int i = 0; i < template.length; i++) {
String line = template[i];
if (line.endsWith("@each-cat@")) {
// ignore
} else if (line.endsWith("@each-R@")) {
int blockEnd = indexAfter(template, i, "@end-R@");
String[] block = stringsIn(template, i+1, blockEnd-1);
for (int rcat1 = rcat; rcat1 <= MAX_RCAT; rcat1++)
expandTemplate(block, false, rcat1, nrefs, nints, nlongs);
VAR.makeBindings(topLevel, rcat, nrefs, nints, nlongs);
i = blockEnd-1; continue;
} else if (line.endsWith("@each-Tv@")) {
int blockEnd = indexAfter(template, i, "@end-Tv@");
String[] block = stringsIn(template, i+1, blockEnd-1);
expandTemplate(block, false, rcat, nrefs, nints, nlongs);
expandTemplateForPrims(block, false, rcat, nargs, nints+1, nlongs+1);
VAR.makeBindings(topLevel, rcat, nrefs, nints, nlongs);
i = blockEnd-1; continue;
} else {
System.out.println(VAR.transform(line));
}
}
}
}
//}}} */
//params=[0, 10, 4, 99, 0, 0]
static class A0 extends Adapter {
protected A0(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A0(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A0 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A0(e, i, c, t); }
protected Object invoke_L0() throws Throwable { return convert_L(invoker.<Object>invokeExact(target)); }
protected Object invoke_I0() throws Throwable { return convert_I(invoker.<int >invokeExact(target)); }
protected Object invoke_J0() throws Throwable { return convert_J(invoker.<long >invokeExact(target)); }
protected Object invoke_F0() throws Throwable { return convert_F(invoker.<float >invokeExact(target)); }
protected Object invoke_D0() throws Throwable { return convert_D(invoker.<double>invokeExact(target)); }
}
static class A1 extends Adapter {
protected A1(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A1(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A1 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A1(e, i, c, t); }
protected Object invoke_L1(Object a0) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0)); }
protected Object invoke_I1(Object a0) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0)); }
protected Object invoke_J1(Object a0) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0)); }
protected Object invoke_F1(Object a0) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0)); }
protected Object invoke_D1(Object a0) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0)); }
}
static class A2 extends Adapter {
protected A2(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A2(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A2 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A2(e, i, c, t); }
protected Object invoke_L2(Object a0, Object a1) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1)); }
protected Object invoke_I2(Object a0, Object a1) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1)); }
protected Object invoke_J2(Object a0, Object a1) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1)); }
protected Object invoke_F2(Object a0, Object a1) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1)); }
protected Object invoke_D2(Object a0, Object a1) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1)); }
}
static class A3 extends Adapter {
protected A3(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A3(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A3 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A3(e, i, c, t); }
protected Object invoke_L3(Object a0, Object a1, Object a2) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1, a2)); }
protected Object invoke_I3(Object a0, Object a1, Object a2) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1, a2)); }
protected Object invoke_J3(Object a0, Object a1, Object a2) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1, a2)); }
protected Object invoke_F3(Object a0, Object a1, Object a2) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1, a2)); }
protected Object invoke_D3(Object a0, Object a1, Object a2) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1, a2)); }
}
static class A4 extends Adapter {
protected A4(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A4(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A4 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A4(e, i, c, t); }
protected Object invoke_L4(Object a0, Object a1, Object a2, Object a3) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1, a2, a3)); }
protected Object invoke_I4(Object a0, Object a1, Object a2, Object a3) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1, a2, a3)); }
protected Object invoke_J4(Object a0, Object a1, Object a2, Object a3) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1, a2, a3)); }
protected Object invoke_F4(Object a0, Object a1, Object a2, Object a3) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1, a2, a3)); }
protected Object invoke_D4(Object a0, Object a1, Object a2, Object a3) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1, a2, a3)); }
}
static class A5 extends Adapter {
protected A5(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A5(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A5 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A5(e, i, c, t); }
protected Object invoke_L5(Object a0, Object a1, Object a2, Object a3, Object a4) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1, a2, a3, a4)); }
protected Object invoke_I5(Object a0, Object a1, Object a2, Object a3, Object a4) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1, a2, a3, a4)); }
protected Object invoke_J5(Object a0, Object a1, Object a2, Object a3, Object a4) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1, a2, a3, a4)); }
protected Object invoke_F5(Object a0, Object a1, Object a2, Object a3, Object a4) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1, a2, a3, a4)); }
protected Object invoke_D5(Object a0, Object a1, Object a2, Object a3, Object a4) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1, a2, a3, a4)); }
}
static class A6 extends Adapter {
protected A6(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A6(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A6 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A6(e, i, c, t); }
protected Object invoke_L6(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1, a2, a3, a4, a5)); }
protected Object invoke_I6(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1, a2, a3, a4, a5)); }
protected Object invoke_J6(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1, a2, a3, a4, a5)); }
protected Object invoke_F6(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1, a2, a3, a4, a5)); }
protected Object invoke_D6(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1, a2, a3, a4, a5)); }
}
static class A7 extends Adapter {
protected A7(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A7(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A7 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A7(e, i, c, t); }
protected Object invoke_L7(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1, a2, a3, a4, a5, a6)); }
protected Object invoke_I7(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1, a2, a3, a4, a5, a6)); }
protected Object invoke_J7(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1, a2, a3, a4, a5, a6)); }
protected Object invoke_F7(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1, a2, a3, a4, a5, a6)); }
protected Object invoke_D7(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1, a2, a3, a4, a5, a6)); }
}
static class A8 extends Adapter {
protected A8(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A8(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A8 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A8(e, i, c, t); }
protected Object invoke_L8(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7)); }
protected Object invoke_I8(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7)); }
protected Object invoke_J8(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7)); }
protected Object invoke_F8(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7)); }
protected Object invoke_D8(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7)); }
}
static class A9 extends Adapter {
protected A9(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A9(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A9 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A9(e, i, c, t); }
protected Object invoke_L9(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8)); }
protected Object invoke_I9(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8)); }
protected Object invoke_J9(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8)); }
protected Object invoke_F9(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8)); }
protected Object invoke_D9(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8)); }
}
static class A10 extends Adapter {
protected A10(MethodHandle entryPoint) { super(entryPoint); } // to build prototype
protected A10(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ super(e, i, c, t); }
protected A10 makeInstance(MethodHandle e, MethodHandle i, MethodHandle c, MethodHandle t)
{ return new A10(e, i, c, t); }
protected Object invoke_L10(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8, Object a9) throws Throwable { return convert_L(invoker.<Object>invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8, a9)); }
protected Object invoke_I10(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8, Object a9) throws Throwable { return convert_I(invoker.<int >invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8, a9)); }
protected Object invoke_J10(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8, Object a9) throws Throwable { return convert_J(invoker.<long >invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8, a9)); }
protected Object invoke_F10(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8, Object a9) throws Throwable { return convert_F(invoker.<float >invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8, a9)); }
protected Object invoke_D10(Object a0, Object a1, Object a2, Object a3, Object a4, Object a5, Object a6, Object a7, Object a8, Object a9) throws Throwable { return convert_D(invoker.<double>invokeExact(target, a0, a1, a2, a3, a4, a5, a6, a7, a8, a9)); }
}
}